Rf tissue sealer, shear grip, trigger lock mechanism and energy activation

ABSTRACT

A variety of surgical instruments include one or more elements that transmit RF energy to tissue. Some such instruments comprise a pair of jaws that open and close on tissue, with conductive tissue contact surfaces that are operable to weld tissue clamped between the jaws. Some surgical instruments also include a translating tissue cutting element. Some such instruments may be in the form of forceps having a scissor grip. Forceps type instruments may in some instances provide a feature that allows the jaws of the forceps to be locked on tissue, so that the operator can remove his or her hands from the instrument. In such an instrument it may also be desirable to provide a circuit that is activated only when the forceps are closed and sufficient pressure is applied to the tissue between the jaws of the device.

INTRODUCTION

The present disclosure relates generally to a radio frequency (RF)cutting forceps and various mechanism associated therewith.

A variety of surgical instruments include one or more elements thattransmit RF energy to tissue (e.g., to coagulate or seal the tissue).Some such instruments comprise a pair of jaws that open and close ontissue, with conductive tissue contact surfaces that are operable toweld tissue clamped between the jaws. In open surgical settings, somesuch instruments may be in the form of forceps having a scissor grip.

In addition to having RF energy transmission elements, some surgicalinstruments also include a translating tissue cutting element. Someversions of electrosurgical instruments that are operable to severtissue may be selectively used in at least two modes. One such mode mayinclude both severing tissue and coagulating tissue. Another such modemay include just coagulating tissue without also severing the tissue.Yet another mode may include the use of jaws to grasp and manipulatetissue without also coagulating and/or severing the tissue.

When an electrosurgical instrument includes grasping jaws and tissuesevering capabilities it may be desirable to avoid accidental cutting bythe knife. Hence, the instrument may include a feature that prevents theknife from firing until the jaws are sufficiently closed upon thetissue. It may also be desirable to prevent the jaws from being openeduntil the knife has been retracted. One or both of these features canprevent the knife from being extended while the jaws are open.

Forceps type instruments may in some instances provide a feature thatallows the jaws of the forceps to be locked on tissue, so that theoperator can remove his or her hands from the instrument. In such aninstrument it may also be desirable to provide a circuit that isactivated only when the forceps are closed and sufficient pressure isapplied to the tissue between the jaws of the device.

SUMMARY

In one embodiment, an electrosurgical instrument for operating on tissuecomprises a first arm, comprising a first handle and a first jaw. Asecond arm is pivotally connected to the first arm. The second armcomprises a second handle; a second jaw comprising an electrode operableto deliver radio frequency (RF) energy to tissue; a knife configured totranslate within slots defined in the first and second jaws; and a pushplate operably connected to the knife such that a proximal motion of thepush plate extends the knife and a distal motion of the push plateretracts the knife. A trigger lock mechanism comprises a switch armpivotally mounted to the first arm, the switch arm comprising a firstend and a second end, wherein the first end extends below the first arm,the trigger lock mechanism configured to prevent the first and secondjaw from being opened.

In one embodiment, the electrosurgical instrument comprises a pull ringintegrated into the push plate for operating the knife.

In one embodiment of the electrosurgical instrument, the first end ofthe switch arm comprises a protrusion.

In one embodiment of the electrosurgical instrument the trigger lockmechanism comprises a slot integrated into the lower arm and configuredto accept the first end of the switch arm, the slot comprising a guideconfigured to direct the first end of the switch arm in a distaldirection, the slot further comprising a lip at the distal side, the lipconfigured to prevent the first end of the switch arm from exiting theslot. The guide of the electrosurgical instrument comprises a ramp uponwhich the protrusion rides.

In one embodiment, the electrosurgical instrument comprises a lockspring, wherein the second end of the switch arm rests against the lockspring and wherein the lock spring is configured to return the switcharm to a neutral position.

In one embodiment of the electrosurgical instrument, the first end ofthe switch arm comprises a lock button pivotally mounted inside thefirst handle and wherein the switch arm is movable between a firstposition and a second position, wherein the second position prevents theswitch arm from returning to a neutral position. The switch arm of theelectrosurgical instrument may be configured to prevent the lock buttonfrom transitioning between the first position and the second positionwhen the switch arm is in the neutral position.

In one embodiment of the electrosurgical instrument, the second armfurther comprises an energy button configured to activate the RF energy.

In another embodiment, an electrosurgical instrument for operating ontissue comprises a first arm comprising a first handle and a first jaw;a second arm pivotally connected to the first arm. The second armcomprising a second handle; a second jaw comprising an electrodeoperable to deliver radio frequency (RF) energy to tissue; a knifeconfigured to translate within slots defined in the first and secondjaws; a push plate operably connected to the knife such that a proximalmotion of the push plate extends the knife and a distal motion of thepush plate retracts the knife; and a trigger lock mechanism configuredto prevent the first and second jaw from being opened. The second armfurther comprises a compression circuit and a compression button foractivating the compression circuit. The compression button is located atthe base of the switch arm slot and is activated by pressure applied bythe switch arm.

In one embodiment, the electrosurgical instrument comprises a pull ringintegrated into the push plate for operating the knife.

In one embodiment of the electrosurgical instrument the second armcomprises an energy button. The energy button of the electrosurgicalinstrument may be configured to activate the RF energy and thecompression circuit is configured to enable an end tone. The RF energyof the electrosurgical instrument may be activated only when both theenergy button and the compression circuit are activated simultaneously.The energy button of the electrosurgical instrument may be configured toactivate the RF energy and the compression circuit may be configured toactivate the RF energy.

In one embodiment of the electrosurgical instrument the compressioncircuit may be configured to enable the RF energy.

In another embodiment, an electrosurgical instrument for operating ontissue comprises a first arm comprising a first handle and a first jaw;a second arm pivotally connected to the first arm, the second armcomprising a second handle; a second jaw comprising an electrodeoperable to deliver radio frequency (RF) energy to tissue; a knifeconfigured to translate within slots defined in the first and secondjaws; a push plate operably connected to the knife such that a proximalmotion of the push plate extends the knife and a distal motion of thering retracts the knife; a compression circuit; and a compressioncircuit button configured to activate the compression circuit.

In one embodiment, the electrosurgical instrument comprises a pull ringintegrated into the push plate for operating the knife.

In one embodiment, the electrosurgical instrument comprises a switch armpivotally mounted to the first arm, the switch arm comprising a firstend and a second end, wherein the first end extends below the first arm;and a switch arm slot integrated into the lower arm and configured toaccept the first end of the switch arm; wherein the compression buttonis located at the base of the switch arm slot and is activated bypressure applied by the switch arm.

In one embodiment of the electrosurgical instrument the switch arm isconfigured to required extra pressure on the first arm for the switcharm to activate the compression button.

In one embodiment, the electrosurgical instrument comprises an energybutton.

In one embodiment of the electrosurgical instrument the energy buttonmay be configured to activate the RF energy and the compression circuitis configured to enable an end tone.

In one embodiment of the electrosurgical instrument the RF energy may beactivated only when both the energy button and the compression circuitare activated simultaneously.

In one embodiment of the electrosurgical instrument the energy buttonmay be configured to activate the RF energy and the compression circuitis configured to activate the RF energy.

In one embodiment of the electrosurgical instrument the compressioncircuit may be configured to enable the RF energy.

FIGURES

The novel features of the embodiments described herein are set forthwith particularity in the appended claims. The embodiments, however,both as to organization and methods of operation may be betterunderstood by reference to the following description, taken inconjunction with the accompanying drawings as follows:

FIG. 1A illustrates a perspective view of one embodiment of an RFcutting forceps (also called a “cutting forceps”) in a closed position;

FIG. 1B illustrates a perspective view of the cutting forceps shown inFIG. 1A in an open position;

FIG. 2 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 1A;

FIG. 3 illustrates an exploded view of the cutting forceps shown in FIG.1A;

FIGS. 4A and 4B illustrate close up views of the jaws of the cuttingforceps shown in FIG. 1A when the cutting forceps are in an openposition;

FIG. 5 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 1A, to illustrate the operation of the knife;

FIG. 6 illustrates a sideways partially transparent view of the cuttingforceps shown in FIG. 1A to illustrate the operation of the RF sealingmechanism;

FIG. 7 illustrates a sideways transparent view of one embodiment of acutting forceps that comprises a knife lockout mechanism;

FIG. 8 illustrates a close-up transparent view of the knife lockoutmechanism of the cutting forceps shown in FIG. 7;

FIG. 9 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 7 with an angled “L” shape slot 1164 and in a partiallyclosed position;

FIG. 10 illustrates a close up transparent view of the distal end of oneembodiment of the cutting forceps shown in FIG. 7 where the knife can bepartially drawn;

FIG. 11 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 7 in a fully closed position, with the knife fullyadvanced;

FIG. 12 illustrates sideways transparent view of an embodiment of acutting forceps with a knife lockout mechanism, in a fully openposition;

FIG. 13 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 12 in a partially closed position;

FIG. 14 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 12 in a nearly closed position;

FIG. 15 illustrates a sideways transparent view of the cutting forcepsshown in FIG. 12 in a fully closed position, with the knife fullyadvanced;

FIG. 16 illustrates a sideways transparent view of one embodiment of acutting forceps with a trigger lockout mechanism.

FIG. 17 illustrates a close-up transparent view of a portion of theproximal end of the cutting forceps shown in FIG. 16;

FIG. 18 illustrates a close-up transparent angled view of one embodimentof the switch arm in the switch arm slot of the cutting forceps shown inFIG. 16;

FIG. 19 illustrates a close-up sideways transparent view of the proximalend of the cutting forceps shown in FIG. 16 and the effect of the rampor guide in the switch arm slot;

FIG. 20 illustrates a close-up sideways transparent view of a portion ofthe proximal end of the cutting forceps shown in FIG. 16, illustratingthe activation of the lock button;

FIG. 21 illustrates a close-up sideways transparent view of the proximalend of the cutting forceps, illustrating how the cutting forceps shownin FIG. 16 can be locked in a closed position;

FIG. 22 illustrates a close-up transparent angled view of the switch armmaking contact with the lip in the switch arm slot of the cuttingforceps shown in FIG. 16;

FIG. 23 illustrates a close-up sideways transparent view of a portion ofthe proximal end of the cutting forceps shown in FIG. 16, illustratinghow the arms of the cutting forceps may be unlocked;

FIG. 24 illustrates as close-up sideways transparent view of oneembodiment of a cutting forceps shown in FIG. 16 where the switch armcan be used to activate, or assist in activating, an RF sealingmechanism;

FIG. 25 illustrates the various components of any of the cutting forcepsshown herein that may provide for different RF energy activationschemes;

FIG. 26A illustrates one embodiment of an electrical circuit that mayprovide the necessary power to generate RF energy;

FIG. 26B illustrates one embodiment of the energy button circuit; and

FIG. 26C illustrates one embodiment of a compression circuit.

DESCRIPTION

The Applicant of the present application also owns the U.S. patentapplications identified below which were filed on even date herewith andwhich are each herein incorporated by reference in their respectiveentireties:

U.S. patent application Ser. No. ______, entitled RF TISSUE SEALER,SHEAR GRIP, TRIGGER LOCK MECHANISM AND ENERGY ACTIVATION (AttorneyDocket No. END7453USNP/140080); and

U.S. patent application Ser. No. ______, entitled TISSUE SEALING ANDCUTTING INSTRUMENT WITH LOCKING FEATURES (Attorney Docket No.END7457USNP/140082).

In the following detailed description, reference is made to theaccompanying drawings, which form a part hereof. In the drawings,similar symbols and reference characters typically identify similarcomponents throughout the several views, unless context dictatesotherwise. The illustrative embodiments described in the detaileddescription, drawings, and claims are not meant to be limiting. Otherembodiments may be utilized, and other changes may be made, withoutdeparting from the scope of the subject matter presented here.

The following description of certain examples of the technology shouldnot be used to limit its scope. Other examples, features, aspects,embodiments, and advantages of the technology will become apparent tothose skilled in the art from the following description, which is by wayof illustration, one of the best modes contemplated for carrying out thetechnology. As will be realized, the technology described herein iscapable of other different and obvious aspects, all without departingfrom the technology. Accordingly, the drawings and descriptions shouldbe regarded as illustrative in nature and not restrictive.

It is further understood that any one or more of the teachings,expressions, embodiments, examples, etc. described herein may becombined with any one or more of the other teachings, expressions,embodiments, examples, etc. that are described herein. Thefollowing-described teachings, expressions, embodiments, examples, etc.should therefore not be viewed in isolation relative to each other.Various suitable ways in which the teachings herein may be combined willbe readily apparent to those of ordinary skill in the art in view of theteachings herein. Such modifications and variations are intended to beincluded within the scope of the claims.

Before explaining the various embodiments of the RF cutting forceps indetail, it should be noted that the various embodiments disclosed hereinare not limited in their application or use to the details ofconstruction and arrangement of parts illustrated in the accompanyingdrawings and description. Rather, the disclosed embodiments may bepositioned or incorporated in other embodiments, variations andmodifications thereof, and may be practiced or carried out in variousways. Accordingly, embodiments of the surgical devices disclosed hereinare illustrative in nature and are not meant to limit the scope orapplication thereof. Furthermore, unless otherwise indicated, the termsand expressions employed herein have been chosen for the purpose ofdescribing the embodiments for the convenience of the reader and are notto limit the scope thereof. In addition, it should be understood thatany one or more of the disclosed embodiments, expressions ofembodiments, and/or examples thereof, can be combined with any one ormore of the other disclosed embodiments, expressions of embodiments,and/or examples thereof, without limitation.

For clarity of disclosure, the terms “proximal” and “distal” are definedherein relative to a human or robotic operator of the surgicalinstrument. The term “proximal” refers the position of an element closerto the human or robotic operator of the surgical instrument and furtheraway from the surgical end effector of the surgical instrument. The term“distal” refers to the position of an element closer to the surgical endeffector of the surgical instrument and further away from the human orrobotic operator of the surgical instrument.

Also, in the following description, it is to be understood that termssuch as front, back, inside, outside, top, bottom, upper, lower and thelike are words of convenience and are not to be construed as limitingterms. Terminology used herein is not meant to be limiting insofar asdevices described herein, or portions thereof, may be attached orutilized in other orientations. The various embodiments will bedescribed in more detail with reference to the drawings.

Overview of Electrosurgical Instrument

An electrosurgical instrument may include a set of jaws, with at leastone of the jaws being pivotable relative to the other jaw to selectivelycompress tissue between the jaws. Once the tissue is compressed,electrodes in the jaws may be activated with bipolar RF energy to sealthe tissue. In some instances, a cutting feature is operable to severtissue that is clamped between the jaws. For instance, the cuttingfeature may be actuated after the RF energy has sealed the tissue.Various references that are cited herein relate to electrosurgicalinstruments where the jaws are part of an end effector at the distal endof an elongate shaft, such that the end effector and the shaft may beinserted through a port (e.g., a trocar) to reach a site within apatient during a minimally invasive endoscopic surgical procedure. Ahandpiece may be positioned at the proximal end of the shaft formanipulating the end effector. Such a handpiece may have a pistol gripconfiguration or some other configuration.

In some instances, it may be desirable to provide an electrosurgicalinstrument that does not have an elongate shaft or handpiece similar tothose described in the various references cited herein. In particular,it may be desirable to provide an electrosurgical instrument that isconfigured similar to a forceps device, with a scissor grip. Suchinstruments may be used in a variety of medical procedures. Variousexamples of electrosurgical shears/forceps devices are disclosed in U.S.Pub. No. 2014/0214019, entitled “Electrosurgical Hand Shears,” publishedJul. 31, 2014, the disclosure of which is incorporated by referenceherein. Various other examples of electrosurgical forceps instrumentswill be described in greater detail below; while other examples will beapparent to those of ordinary skill in the art in view of the teachingsherein.

Various embodiments of electrosurgical shears or forceps with RF energyfor sealing tissue may be provided. One such embodiment may provide adistal energy switch and a proximal energy switch. Such an embodimentmay operate as follows: first, the jaws of the device are closed ontissue. Once the jaws are closed on tissue, the proximal energy switchmay or may not be activated. Second, the distal energy switch isactivated. Activation of the distal energy switch delivers RF energy tothe tissue. In some embodiments, if the proximal energy switch has notbeen activated, a warning may be issued, such as for instance by anexternal generator that provides power to the device. Third, aprocessor, possibly located in the cutting forceps or possibly locatedin the power generator, determines when the tissue has been sufficientlyheated to be sealed. Fourth, a tone or signal may be issued when it hasbeen determined that the tissue is sealed and is ready to cut. If theproximal energy switch has not been activated the tone may not issueand/or a warning may be signaled. In some embodiments, the end tone isdependent on the impedance of the tissue between the jaws. Fifth, thedistal energy button is released. Sixth, a knife cuts the tissue betweenthe jaws by way of a knife trigger. Seventh, the knife is returned to astarting position. Eight, the jaws are opened to release the tissue.

Another embodiment of an electrosurgical shears or forceps with RFenergy for sealing tissue may provide a distal energy switch and aproximal energy switch. The operation of such an embodiment may be asfollows: first, the jaws are closed on tissue. Once the jaws are closedon tissue, the proximal energy switch may or may not be activated.Second, the distal energy switch is activated. The RF energy will not beactivated if the proximal energy switch has not been activated. Awarning may be issued, such as by instance by the external generator.When the proximal energy switch is activated, thus activating the RFenergy, then third, a processor, possibly located in the cutting forcepsor possibly located in the power generator, determines when the tissuehas been sufficiently heated to be sealed. Fourth, a tone or signal maybe issued when it has been determined that the tissue is sealed and isready to cut. In some embodiments, the end tone is dependent on theimpedance of the tissue between the jaws. Fifth, the distal energybutton is released. Sixth, a knife cuts the tissue between the jaws byway of a knife trigger. Seventh, the knife is returned to a startingposition. Eight, the jaws are opened to release the tissue.

Another embodiment of an electrosurgical shears or forceps with RFenergy for sealing tissue may provide a proximal energy switch. Theoperation of such an embodiment may be as follows: first, the jaws areclosed on tissue. Once the jaws are closed on tissue, the proximalenergy switch may or may not be activated. Second, the upper forceps armmay be closed and flexed to activate the proximal energy switch. Aswitch arm attached to the upper forceps arm may be configured to touchand activate the proximal energy switch. Third, a processor, possiblylocated in the cutting forceps or possibly located in the powergenerator, determines when the tissue has been sufficiently heated to besealed. Fourth, a tone or signal may be issued when it has beendetermined that the tissue is sealed and is ready to cut. At the sametime, the RF energy may be deactivated automatically, withoutdeactivation of the proximal energy switch. Fifth, a knife cuts thetissue between the jaws by way of a knife trigger. Sixth, the knife isreturned to a starting position. Seventh, the jaws are opened to releasethe tissue.

Cutting Forceps

One embodiment of an RF cutting forceps comprises a first or upper armpivotally connect to a second or lower arm. The upper arm comprises afirst or upper handle ring and a first or lower jaw. The lower armcomprises a second or lower handle ring, a lower arm body, and a secondor upper jaw. The lower arm body comprises a pull ring operativelyconnected to a knife. The knife is configured to translate distallybetween the jaws to sever tissue held by the jaws.

Another embodiment of an RF cutting forceps comprises the upper andlower arms as descried above, and additionally comprises a knife lockoutmechanism. The knife lockout mechanism comprises a movement arm and aslot. The slot is integrated into a push plate, which also comprises thepull ring. The movement arm is pivotally connected at a first end to theupper arm and is driven by the upper arm as the upper arm opens andcloses. At the second end of the movement arm is a lower movement armpin that rides in the slot. In some embodiments, the upper portion ofthe slot is positioned at an angle that prevents the pull ring frombeing drawn so long as the lower movement arm pin is within the upperportion of the slot. In some embodiments, the lower portion of the slotis positioned horizontally to the direction of motion of the pull ring.In such embodiments, the pull ring can be drawn when the lower movementarm pin is in the lower portion of the slot, but the jaws cannot beopened so long as the lower movement arm pin is located in the lowerportion of the slot.

Another embodiment of an RF cutting forceps comprises the upper andlower arms as described above, and additionally comprises a triggerlockout mechanism. The trigger lockout mechanism comprises a lockbutton, a switch arm, and a switch arm slot. The switch arm comprises afirst end that extends below the upper arm. The switch arm slot ispositioned within the lower arm body to receive the first end of theswitch arm. In some embodiments, the switch arm slot may comprise aguide or ramp that causes the switch arm to pivot such that the firstend can be trapped by a lip within the switch arm slot. The lock buttonmay be configured to maintain the locked position of the switch armslot. In some embodiments, the RF cutting forceps also comprises acompression circuit that is activated by a compression circuit button.In such embodiments, the compression circuit button is positioned at thebase of the switch arm slot, such that it can be activated by thepressure applied by the switch arm.

FIG. 1A illustrates a perspective view of one embodiment of an RFcutting forceps 100 (also called a “cutting forceps”) in a closedposition. The cutting forceps 100 comprises an upper arm 102 and a lowerarm 104 pivotally connected at a pivot joint 118 near the distal end ofthe device. The upper 102 and lower arm 104 are shaped such that thecutting forceps 100 can be operated by either a left-handed orright-handed person. The cutting forceps 100 can also be operated asillustrated or upside down from how it is illustrated. As such, theterms upper and lower and left and right are used for convenience only,and not as a limitation.

The upper arm 102 comprises a first or upper handle ring 106 near theproximal end of the upper arm 102, a bend arm 108 between the proximaland distal ends, and a first or lower jaw 110 at the distal end. Theupper handle ring 106 is shaped such that a human finger can be insertedtherein. In some embodiments, the upper handle ring 106 comprises a lockbutton 168 and switch arm 172, described in further detail below. Thebend arm 108 connects the upper handle ring 106 to the lower jaw 110.The upper handle ring 106, bend arm 108, and lower jaw 110 are connectedin a fixed orientation, such that as the upper handle ring 106 is movedall parts of the upper arm 102 move together.

The lower arm 104 comprises a lower arm body 112 and a second or upperjaw 116. Integrated with the proximal end of the lower arm body 112 is asecond or lower handle ring 114. The lower handle ring 114 is shapedsuch that a human finger can be inserted therein. The distal end of thelower arm body 112 is connected to the upper jaw 116. The lower arm body112, the lower handle ring 114, and the upper jaw 116 are connected in afixed orientation, such that all parts of the lower arm 104 movetogether. The lower arm body 112 further comprises a pull ring 130 forcontrolling the operation of the knife 120, described in further detailbelow. In some embodiments the lower arm body 112 also comprises anenergy button 142 for activating the RF energy, also described infurther detail below. The lower arm body 112 also comprises a bump 148that prevents accidental activation of the energy button 142.

FIG. 1B illustrates a perspective view of the cutting forceps 100 shownin FIG. 1A in an open position. As explained above, the upper arm 102 ispivotally connected at a pivot joint 118 to the lower arm 104 near thedistal end of the cutting forceps 100. As the upper arm 102 is raised,the proximal end of the upper arm 102 pivots away from the lower arm104. At the same time, the lower jaw 110 pivots away from the upper jaw116, thus opening the jaws 110, 116. The motion of the upper arm 102relative to the lower arm 104 can also be described as a scissor motion.The upper arm 102 can be lowered to return the cutting forceps 100 tothe closed position illustrated in FIG. 1A. As illustrated in FIG. 1B,in some embodiments, the upper arm 102 is also connected to a first endof a movement arm 160; the second end of the movement arm 160 isconnected to an internal component of the lower arm body 112.Embodiments including the movement arm 160 are described in furtherdetail below. In some embodiments the lower arm body 112 includes aswitch arm slot 174 for receiving the switch arm 172. Embodimentsincluding the switch arm 172 and switch arm slot 174 are described infurther detail below.

FIG. 2 illustrates a sideways transparent view of the cutting forceps100 shown in FIG. 1A. As illustrated in FIG. 2, the lower arm body 112comprises a knife 120 and the mechanism for driving the knife 120,comprising a pull ring 130, a sliding or push plate 132, a return spring134, a push arm 124, and a slide 122. The pull ring 130 provides theoperator of the instrument control of the knife 120. The pull ring 130is integrated into the push plate 132. The push plate 132 is mountedwithin the lower arm body 112 such that it is able to slide along theproximal-distal axis of the device. At its proximal side, the push plate132 rests against the return spring 134. When the return spring 134 isin a relaxed or minimally compressed orientation, the push plate 132 isin a distal or neutral position; that is the pull ring 132 is furtheraway from the operator of the device and the knife 120 is retracted. Thepush arm 124 is pivotally connected by two push arm pins 126 a, 126 b toa push plate 132. The push arm pins 126 a, 126 b are mounted withinslots 128 a, 128 b in the lower arm body 112 and the push plate 132 suchthat the push arm pins 126 a, 126 b can slide within the slots 128 a,128 b. The lower end of the push arm 124 rests against the proximal endof the slide 122. The distal end of the slide 122 is connected to thedistal end of the knife 120. The proximal end of the knife 120 ispositioned to translate distally between the upper 116 and lower 110jaws. The operation of the knife 120 is further described below. In oneembodiment, the push plate 132 may be replaced with a ring plate,without limitation.

FIG. 2 also illustrates the components of one embodiment of an RFsealing mechanism. The RF sealing mechanism comprises an electrode 136that extends along the length of the jaws 110, 116 and into the lowerarm body 112. Within the jaws 110, 116, the electrode 136 is partiallysurrounded by an insulator 138. In some embodiments, the electrode 136is connected at its proximal end to an energy button circuit 140. Theenergy button circuit 140 is activated by the energy button 142, whichactivates the RF energy produced by the electrode 136. A port 144 in theproximal end of the lower arm body 112 is provided for connecting acable (not shown) that provides an energy source to power the energybutton circuit 140 and to generate the RF energy. The operation of theRF sealing mechanism is further described below.

FIG. 2 also illustrates the components of an embodiment of a knife lockout mechanism that may be included in some embodiments of the cuttingforceps 100. The knife 120 lock out mechanism comprises the movement arm160, an upper movement arm pin 162 b, a lower movement arm pin 162 a,and a slot 164 in the push plate 132. The operation of the lock outmechanism is described in further detail below.

FIG. 2 also illustrates the components of an embodiment of a triggerlock mechanism that may be included in some embodiments of the cuttingforceps 100. The trigger lock mechanism comprises a lock button 168, aswitch arm 172, a lock spring 170, a switch arm slot 174, a compressioncircuit 176, and a compression circuit button 178. The operation of thetrigger lock mechanism is described in further detail below.

FIG. 3 illustrates an exploded view of the cutting forceps 100 shown inFIG. 1A. Illustrated are the constituent components of the cuttingforceps 100, as well the components of various embodiments of thecutting forceps 100. The components of the cutting forceps 100 comprisean upper arm 102 and a lower arm 104, a cutting mechanism, and a sealingor coagulating mechanism.

The upper arm 102 comprises a bend arm 108 and an upper handle ring 106integrally connected therewith. The upper arm 102 also comprises a lowerjaw 110 configured to be connected to the distal end of the bend arm108.

The lower arm 104 comprises an upper jaw 116. The upper jaw 116 isconfigured to be secured at its proximal end to an upper jaw tail 150.The upper jaw 116 comprises an electrode 136 that extends along thelength of the upper jaw 116. The electrode 136 is partially surroundedby an insulator 138. The proximal end of the electrode 136 is coupled toan electrode connector 152. The electrode connector 152 connects theelectrode 136 by means of wiring to the port 144 at the proximal end ofthe lower arm body 112 to receive power. The electrode connector 152 mayalso connect the electrode 136 to the energy button circuit 140. Theenergy button circuit 140 is connected to an energy button 142, shownhere in exploded view as having a left 153 a and a right 153 part, suchthat the energy button 142 can be operated from either the left or theright side of the cutting forceps 100. The energy button 142 alsocomprises a rocker 154 that is configured to allow the energy button 142to pivot. A return connector 158 provides a connection to a returnelectrical path to the port 144.

The lower arm 104 also comprises a knife 120 for cutting tissue. Theknife 120 is configured to connect at its proximal end to a slide 122,where the slide 122 is operable to push the knife 120 forwards (that is,towards the distal end of the cutting forceps 100) and retract the knife120 backwards. The slide 122 is configured to connect at its proximalend to a push arm 124. The push arm 124 pivots on an upper push arm pin126 a and a lower push arm pin 126 b. The upper push arm pin 126 a restswithin a slot 128 a in the right lower arm body cover 146 b. The lowerpush arm pin 126 b rests within a slot 128 b in a push plate 132. Bothpush arm pins 126 a, 126 b are configured to move within theirrespective slots 128 a, 128 b as the push plate 132 moves backwards(that is, towards the proximal end of the cutting forceps 100) andforwards. The push plate 132 comprises a pull ring 130 configured toreceive a human finger. The push plate 132 rests against a return spring134. The operating of the knife 120 is discussed in further detailbelow.

A left lower arm body cover 146 a and a right lower arm body cover 146 benclose the knife 120 and its related parts, the electrode 136 and itsrelated parts, and the upper jaw 116 and its related parts, except forthe distal end of the upper jaw 116.

In some embodiments, the left lower arm body cover 146 a and right lowerarm body cover 146 b also enclose a knife lock out mechanism. The knifelockout mechanism comprises a movement arm 160 and a slot 164 in thepush plate 132. The knife lockout mechanism is described in furtherdetail below.

In some embodiments, the cutting forceps 100 also comprises a triggerlock mechanism. The trigger lock mechanism comprises a lock button 168,a lock spring 170, and a switch arm 172 integrated with the upper handlering 106 and fully or partially contained therein by an upper handlering cover 166. The left 146 a and right 146 b lower body coverscomprise a switch arm slot 174 for receiving the switch arm 172.Composed within the lower body 112 is a compression circuit 176 thatcomprises a compression circuit button 178. The trigger lock mechanismis described in further detail below.

FIGS. 4A and 4B illustrate close up views of the jaws 110, 116 of thecutting forceps 100 when the cutting forceps 100 shown in FIG. 1A are inan open position. FIG. 4A illustrates the cutting forceps 100 such thatthe first or lower jaw 110 is oriented downwards. The lower jaw 110comprises a slot 180 configured so that a knife 120 housed within thelower arm 104 of the cutting forceps 100 can translate therein. Thelower jaw 110 also comprises a tissue stop 182 configured to limit orblock tissue within the jaws 110, 116 from advancing any further towardsthe proximal end of the jaws 110, 116. In some embodiments, thetissue-facing surface of the lower jaw 110 is smooth.

FIG. 4B illustrates the cutting forceps 100 such that the second orupper jaw 116 is oriented downwards and such that the tissue-facingsurface of the upper jaw 116 is visible. The upper jaw 116 comprises anelectrode 136 partially surrounded by an insulator 138. The electrode136 extends from the interior of the lower arm body 112 along one sideof the upper jaw 116 to the distal end of the upper jaw 116 and returnsalong the other side of the upper jaw 116, ending behind the tissue stop182. The body of the electrode 136 thus forms a slot 180 within whichthe knife 120 can translate. Placed along the tissue-facing surface ofthe electrode 136 are one or more non-conductive teeth 184 configured toassist in gripping tissue placed between the jaws 110, 116. At thedistal end of the upper jaw 116 is located an electrically conductivejaw stop 186 whose height above the tissue-facing surface of the upperjaw 116 sets the gap between the jaws 110, 116.

FIG. 5 illustrates a sideways transparent view of the cutting forceps100 shown in FIG. 1A, to illustrate the operation of the knife 120. Theknife 120 is configured to cut or sever tissue held between the jaws110, 116 of the instrument. The knife mechanism comprises the knife 120,a slide 122, a push arm 124, a push plate 132, a pull ring 130integrated into the push plate 132, and a return spring 134.

Operation of the knife 120 is initiated by drawing or pulling 200 thepull ring 130 in the proximal direction. As the push plate 132 moves inthe proximal direction, it causes the push arm 124 to pivot 202, suchthat the upper or first end of the push arm 124 to moves proximallywhile the lower or second end of the push arm 124 moves distally. Thedistal motion of the lower end of the push arm 124 pushes 204 the slide122 in a distal direction. The distal motion of the slide 122 pushes 206the knife 120 in the distal direction, such that the knife translatesdistally between the jaws 110, 116.

As the push plate 132 is drawn 200, it applies pressure on andcompresses the return spring 134. Once the operator releases the pullring 130, the return spring 134 pushes the push plate 132 in a distaldirection and back into the neutral position. The distal motion of thepush plate 132 reverses the movement of the push arm 124, the slide 122,and the knife 120, thus retracting the knife 120 from the jaws 110, 116.

FIG. 6 illustrates a sideways partially transparent view of the cuttingforceps 100 shown in FIG. 1A to illustrate the operation of the RFsealing mechanism. RF energy may be used to seal or coagulate tissueheld between the jaws 110, 116 of the cutting forceps 100. The RFsealing mechanism comprises an energy button 142, an energy buttoncircuit (not visible), and an electrode 136. The RF energy is activatedby the energy button 142, which is configured to rotate around a pivot156. A bump 148 on the exterior of the instrument prevents inadvertentactivation of the energy button 142. Rotation of the energy button 142informs the energy button circuit to activate the RF energy. RF energyis delivered by the electrode 136 to the jaws 110, 116 of the cuttingforceps 100. Releasing the energy button 142 stops delivery of RF energyby the electrode 136.

The knife mechanism described with respect to FIG. 5 and the RF sealingmechanism described with respect to FIG. 6 can be used separately ortogether. That is, the operator of the instrument can choose to activatethe knife without also activating the RF energy. Similarly, the operatorcan choose to activate the RF energy without also activating the knife.The operator can also choose to seal and cut, typically in that order,by activating the RF energy and subsequently activating the knife.

Knife Lockout

Safe and effective operation of the knife, as described above, may raiseat least two concerns that may be addressed by a knife lockoutmechanism. First, it may be desirable to prevent the knife from firinguntil the jaws are sufficiently closed to cut the tissue held by thejaws. Second, it may be desirable to prevent the jaws from opening untilthe knife has been retracted. The first safety concern seeks to preventthe jaws from being wider apart than the knife is tall, so that theknife will always cut through all layers of the tissue held by the jaws.The second safety concern seeks to prevent the knife from being exposedand inadvertently cutting tissue that was not meant to be cut.

FIG. 7 illustrates a sideways transparent view of one embodiment of acutting forceps 1100 that comprises a knife lockout mechanism. Thecutting forceps 1100 is similar to the cutting forceps 100 of FIGS. 1-6.As illustrated in FIG. 7, the cutting forceps 1100 comprises an upperarm 1102 pivotally connected to a lower arm 1104 at a pivot joint 1118.The upper arm 1102 is connected to a lower jaw 1110 and comprises anupper handle ring 1106 shaped such that a human finger can be insertedtherein. The lower arm 1104 comprises a lower arm body 1112, a lowerhandle ring 1114, and an upper jaw 1116. The lower arm body 1112comprises an electrode 1136 for supplying RF energy, wherein theelectrode 1136 extends from the lower arm body 1112 along the length ofthe jaws 1110, 1116. The lower arm body 1112 also comprises a knife 1120that is connected to a slide 1122. The slide 1122 is pushed and pulledat its proximal end by a push arm 1124. The push arm 1124 is pivotallyconnected to a push plate 1132. The push plate 1132 comprises a pullring 1130, wherein the pull ring 1130 is shaped to accept a humanfinger. The proximal side of the push plate 1132 rests against a returnspring 1134 that is operable to return the push plate 1132 to a neutralposition from a drawn position.

The cutting forceps 1100 also comprises a knife lockout mechanism. Theknife lockout mechanism comprises a movement arm 1160 and a slot 1164.The movement arm 1160 provides a link between the upper arm 1102 of thecutting forceps 1100 and the knife firing mechanism, that is, the pullring 1130 and the push plate 1132. The lower or second end of themovement arm 1160 is connected to a lower movement arm pin 1162 a. Thelower movement arm pin 1162 a rides in the slot 1164. The slot 1164 iscut into the push plate 1132 and thus moves in tandem with the pushplate 1132 as the push plate 1132 causes the knife 1120 to be fired andretracted. The upper or first end of the movement arm 1160 is pivotallyconnected to the upper arm 1102 of the cutting forceps 1100 by way of anupper movement arm pin 1162 b.

FIG. 7 illustrates the cutting forceps 1100 in an open position, thatis, with the jaws 1110, 1116 fully parted. In this position, the lowermovement arm pin 1162 a rests at the top of the slot 1164. The slot 1164is shaped such that the lower movement arm pin 1162 a prevents the pushplate 1132 from moving until the jaws 1110, 1116 are partially orentirely closed.

FIG. 8 illustrates a close-up transparent view of the knife lockoutmechanism of the cutting forceps shown in FIG. 7. As illustrated by FIG.8, the slot 1164 is cut into the push plate 1132. The lower movement armpin 1162 a rides in the slot 1164. When the cutting forceps 1100 are inthe fully open position, the lower movement arm pin 1162 a rests at oneend of the slot 1164.

In some embodiments, the slot 1164 comprises an angled “L” shape suchthat upper or upright arm portion of the slot is at an angle to thedirection of travel of the push plate 1132 and the lower or horizontalportion of the slot 1164 is parallel to the direction of travel of thepush plate 1132. In such embodiments, the angle of the upright portionof the slot 1164 and the location of the lower movement arm pin 1162 awithin the upright portion of the slot 1164 prevents the push plate 1132from moving forwards or backwards. The lower movement arm pin 1162 amust travel to the horizontal portion of the slot 1164 in order for thepush plate 1132 to be able to move. The horizontal portion of the slot1164 is positioned parallel to the direction of travel of the push plate1132. The position of lower movement arm pin 1162 a within thehorizontal portion of the slot 1164 thus operates to prevent the cuttingforceps 1100 from being opened. The push plate 1132 must be returned tothe neutral position such that the lower movement arm pin 1162 a canaccess the upright portion of the slot 1164 before the cutting forceps1100 can be opened.

In some embodiments, the slot 1164 comprises a vertical shape (notshown) such that the body of slot is perpendicular to the direction oftravel of the push plate 1132. In such embodiments, the slot 1164 causesthe movement of the upper arm 1102 and the push plate 1132 to beproportional, such that as the upper arm 1102 moves up (that, is intothe open position) the push plate 1132 moves towards the distal end ofthe instrument, into the neutral position. Similarly, as the upper arm1102 moves down (that is, into the closed position), the push plate 1132moves towards the proximal end of the instrument and may cause the knife1120 to be extended.

FIG. 9 illustrates a sideways transparent view of the cutting forceps1100 shown in FIG. 7 with an angled “L” shape slot 1164 and in apartially closed position. As the upper arm 1102 moves towards theclosed position, it drives the movement arm 1160 such that the movementarm 1160 pivots at the upper movement arm pin 1162 b. The lower movementarm pin 1162 a rides along the upper or upright portion of the slot 1164until the lower movement arm pin 1162 a reaches the lower or horizontalportion of the slot 1164. Near the top of the horizontal portion of theslot 1164 there may be some play between the lower movement arm pin 1162a and the slot 1164 such that the push plate 1132 can move; however, theknife 1130 will only be able to advance slightly, and not far enough tocut any tissue, due to the lower movement arm pin 1162 being blocked bythe edge of the slot 1164. The lower movement arm pin 1162 a may reachthe horizontal portion of the slot 1164 when the jaws 1110, 1116 arepartially closed, such as for instance at five degrees relative to eachother. Once the lower movement arm pin 1162 a reaches the horizontalportion of the slot 1164, the push plate 1132 may be free to move.

In some embodiments, the slot 1164 is shaped such that the knife 1120can be partially drawn when the jaws 1110, 1116 are partially closed.FIG. 10 illustrates a close up transparent view of the distal end of onesuch embodiment of the cutting forceps 1100 shown in FIG. 7. In theembodiment of FIG. 10, the slot 1164 comprises a first stop 1188. Thefirst stop 1188 prevents the push plate 1132 from being drawn past acertain distance, thus allowing the knife 1120 to only advance a partialdistance along the jaws 1110, 1116. This allows for partial cutting oftissue. For example, when the jaws 1110, 1116 are at five degreesrelative to each other, the first stop 1188 may be positioned such thatthe knife 1120 can advance 0.07 inches from the initial cuttingposition. The slot 1164 may comprise additional stops; for instance, atthree degrees between the jaws 1110, 1116, the knife 1120 may be able toadvance 0.3 inches from the initial cutting position. After the finalstop, the knife 1120 is able to complete a full stroke. For example, attwo to zero degrees between the jaws, the knife 1120 can advance alongthe entire length of the jaws 1110, 1116.

FIG. 11 illustrates a sideways transparent view of the cutting forceps1100 shown in FIG. 7 in a fully closed position, with the knife 1120fully advanced. When the cutting forceps 1100 are in the fully closedposition, the lower movement arm pin 1162 a has full access to thehorizontal portion of the slot 1164, and the push plate 1132 is free tobe pulled to its full extent. In this position, the push plate 1132 isfully drawn and the knife 1120 is fully advanced. The position of thelower movement arm pin 1162 a in the horizontal portion of the slot 1164prevents the cutting forceps 1100 from being opened while the knife 1120is extended. Once the push plate 1132 is returned to the neutralposition, thus retracting the knife 1120, the lower movement arm pin1162 a can once again travel up the upper portion of the slot 1164,allowing the cutting forceps 1100 to be opened.

FIG. 12 illustrates sideways transparent view of one embodiment of acutting forceps 2100 with a knife lockout mechanism, in a fully openposition. The cutting forceps 2100 is similar to the cutting forceps 100of FIGS. 1-6. As illustrated in FIG. 12, the cutting forceps 2100comprises an upper arm 2102 pivotally connected to a lower arm 2104 at apivot joint 2118. The upper arm 2102 is connected to a lower jaw 2110and comprises an upper handle ring 2106 shaped such that a human fingercan be inserted therein. The lower arm 2104 comprises a lower arm body2112, a lower handle ring 2114, and an upper jaw 2116. The lower armbody 2112 comprises an electrode 2136 for supplying RF energy, whereinthe electrode 2136 extends from the lower arm body 2112 along the lengthof the jaws 2110, 2116. The lower arm body 2112 also comprises a knife2120 that is connected to a slide 2122. The slide 2122 is pushed andpulled at its proximal end by a push arm 2124. The push arm 2124 ispivotally connected to a push plate 2132. The push plate 2132 comprisesa pull ring 2130, wherein the pull ring 2130 is shaped to accept a humanfinger. The proximal side of the push plate 2132 rests against a returnspring 2134 that is operable to return the push plate 2132 to a neutralposition from a drawn position.

The cutting forceps 2100 also comprises a knife lockout mechanism. Theknife lockout mechanism comprises a movement arm 2160 and a slot 2164.The movement arm 2160 provides a link between the upper arm 2102 of thecutting forceps 2100 and the knife firing mechanism, that is, the pullring 2130 and the push plate 2132. The lower or second end of themovement arm 2160 is connected to a lower movement arm pin 2162 a. Thelower movement arm pin 2162 a rides in the slot 2164. The slot 2164 iscut into the push plate 2132 and thus moves in tandem with the pushplate 2132 as the push plate 2132 causes the knife 2120 to be fired andretracted. The upper or first end of the movement arm 2160 is pivotallyconnected to the upper arm 2102 of the cutting forceps 2100 by way of anupper movement arm pin 2162 b.

FIG. 12 illustrates the cutting forceps 2100 in an open position, thatis, with the jaws 2110, 2116 fully parted. In this position, the lowermovement arm pin 2162 a rests at one end of the slot 2164.

FIG. 13 illustrates a sideways transparent view of the cutting forceps2100 shown in FIG. 12 in a partially closed position. As the upper arm2102 moves 2208 towards the closed position, it drives 2210 the movementarm 2160 such that the movement arm 2160 pivots at the upper movementarm pin 2162 b. The lower movement arm pin 2162 a rides along the upperor upright portion of the slot 2164. The lower movement arm pin 2162 amay reach the lower or horizontal portion of the slot 2164 when the jaws2110, 2116 are partially closed, such as for instance at five degreesrelative to each other. Once the lower movement arm pin 2162 a reachesthe horizontal portion of the slot 2164, the push plate 2132 may be freeto be drawn 2200. When the push plate 2132 is drawn 2200 in the proximaldirection, it causes the push arm 2124 to push 2204 the slide 2122, asdescribed above.

In some embodiments, the slot 2164 is shaped such that the knife 2120can be partially drawn when the jaws 2110, 2116 are partially closed.FIG. 14 illustrates a sideways transparent view of the cutting forceps2100 shown in FIG. 12 in a nearly closed position. In some embodiments,the slot 2164 may comprise a first stop. The first stop prevents thepush plate 2132 from being drawn past a certain distance, thus allowingthe knife 2120 to only advance a partial distance along the jaws 2110,2116. This allows for partial cutting of tissue. For example, when thejaws 2110, 2116 are at five degrees relative to each other, the firststop may be positioned such that the knife 2120 can advance 0.07 inchesfrom the initial cutting position. The slot 2164 may comprise additionalstops; for instance, at three degrees between the jaws 2110, 2116, theknife 2120 may be able to advance 0.3 inches from the initial cuttingposition. After the final stop, the knife 2120 is able to complete afull stroke. For example, at two to zero degrees between the jaws, theknife 2120 can advance along the entire length of the jaws 2110, 2116.

FIG. 15 illustrates a sideways transparent view of the cutting forceps2100 shown in FIG. 12 in a fully closed position, with the knife 2120fully advanced. When the cutting forceps 2100 are in the fully closedposition, the lower movement arm pin 2162 a has full access to thehorizontal portion of the slot 2164, and the push plate 2132 is free tomove to its full extent. In this position, the push plate 2132 is fullydrawn 2200 and the knife 2120 is fully advanced 2206. The position ofthe lower movement arm pin 2162 a in the horizontal portion of the slot2164 prevents the cutting forceps 2100 from being opened while the knife2120 is extended. Once the push plate 2132 has returned to the neutralposition, thus retracting the knife 2120, the lower movement arm pin2162 a can once again travel up the upper portion of the slot 2164,allowing the cutting forceps 2100 to be opened.

Trigger Lockout

When using a cutting forceps as described above, it may be desirable tolock the jaws shut on tissue. This allows the operator to remove his orher hands from the device and use the cutting forceps similar to asurgical clamp. The cutting forceps should only lock when desired andnot automatically.

The RF energy that seals or coagulates tissue should also only beactivated at the desired time. Specifically, it may be desirable toactivate the RF energy only when there is sufficient pressure on thejaws of the device. This typically occurs when the forceps arms arefully closed and one arm is possibly flexing to provide a load on thedistal ends of the jaws. Thus it is desirable that the RF energyactivation be disabled unless the jaws are fully closed. It is alsodesirable, however, for the operator to be able to close the jaws of thedevice without activating the RF energy.

FIG. 16 illustrates a sideways transparent view of one embodiment of acutting forceps 3100 with a trigger lockout mechanism. The cuttingforceps 3100 is similar to the cutting forceps 100 of FIGS. 1-6. Asillustrated in FIG. 7, the cutting forceps 3100 comprises an upper arm3102 pivotally connected to a lower arm 3104 at a pivot joint 3118. Theupper arm 3102 is connected to a lower jaw 3110 and comprises an upperhandle ring 3106 shaped such that a human finger can be insertedtherein. The lower arm 3104 comprises a lower arm body, a lower handlering 3114, and an upper jaw 3116. The lower arm body comprises anelectrode 3136 for supplying RF energy, wherein the electrode 3136extends from the lower arm body along the length of the jaws 3110, 3116.The lower arm body also comprises a knife 3120 that is connected to aslide 3122. The slide 3122 is pushed and pulled at its proximal end by apush arm 3124. The push arm 3124 is pivotally connected to a push plate3132. The push plate 3132 comprises a pull ring 3130, wherein the pullring 3130 is shaped to accept a human finger. The proximal side of thepush plate 3132 rests against a return spring 3134 that is operable toreturn the push plate 3132 to a neutral position from a drawn position.

The cutting forceps 3100 also comprises a trigger lockout mechanism. Thetrigger lockout mechanism comprises a lock button 3168, a lock spring3170, a switch arm 3172, and a switch arm slot 3174. The lock button3168 is integrated into the upper handle ring 3106 such that it can beaccessed by a human finger inserted into the upper handle ring 3106. Theswitch arm 3172 is rotatably mounted in the upper arm 3102 and comprisesa first end that extends from the upper arm 3102 underneath the upperhandle ring 3106 and towards the lower arm 3104. The switch arm 3172also comprises a second end that rests against the lock spring 3170. Theswitch arm slot 3174 is located in the lower arm 3104 such that thefirst end of the switch arm 3172 will pass into the switch arm slot 3174when the forceps arms 3102, 3104 are closed.

FIG. 17 illustrates a close-up transparent view of a portion of theproximal end of the cutting forceps 3100 shown in FIG. 16. Illustratedis the neutral position of the switch arm 3172, in which is the lockspring 3170 is relaxed or minimally compressed and the switch arm 3172is positioned to enter and exit the switch arm slot 3174 with ease. Alsoillustrated is a first position of the lock button 3168. In thisposition, the lock button 3168 makes contact with the switch arm 3172 ata first contact point 3300 at the proximal end of the lock button 3168.The first contact point 3300 is such that the switch arm 3172 preventsthe lock button 3168 from moving, effectively locking the lock button3168 in the first position.

FIG. 17 also illustrates the point at which the upper 3102 and lower3104 arms of the cutting forceps 3100 shown in FIG. 16 have initiallybeen closed, such that the switch arm 3172 has entered the switch armslot 3174. As the switch arm 3172 enters the switch arm slot 3174, aprotrusion 3302 on the end of the switch arm 3172 makes contact with aramp or guide or slot path 3304 in the switch arm slot 3174.

FIG. 18 illustrates a close-up transparent angled view of one embodimentof the switch arm 3172 in the switch arm slot 3174 of the cuttingforceps shown in FIG. 16. In the illustrated embodiment, the ramp 3304is in the wall of the switch arm slot 3174 and the protrusion 3302 onthe first end of the switch arm 3172 rests on the ramp 3304. The switcharm slot 3174 may be symmetrical, such that there is a ramp on bothwalls of the switch arm slot 3174, with correspondingly symmetricalprotrusions 3302 on the first end of the switch arm 3172.

FIG. 19 illustrates a close-up sideways transparent view of the proximalend of the cutting forceps 3100 shown in FIG. 16 and the effect of theramp or guide 3304 in the switch arm slot 3174. As the arms 3102, 3104of the cutting forceps 3100 are closed, the guide 3304 directs 3222 thefirst end of the switch arm 1164 towards the distal end of the device.In the illustrated embodiment, the protrusion 3302 rides along the ramp3304 in a distal direction. The switch arm 3172 is pivotally mounted,and thus rotates 3220, applying pressure on the lock spring 3170. Therotation 3220 of the switch arm 3172 also removes the first contactpoint 3300, thus unlocking the lock button 3168.

FIG. 20 illustrates a close-up sideways transparent view of a portion ofthe proximal end of the cutting forceps 3100 shown in FIG. 16,illustrating a second position of the lock button 3168. The lock button3168 can be activated by applying pressure 3224 on the proximal end. Thelock button 3168 is pivotally mounted within the upper arm 3102, andthus as pressure 3224 is applied to the proximal end of the lock button3168 the lock button 3168 rotates 3226. As it rotates 3266, the proximalend of the lock button 3168 reaches a second contact point 3308 on theswitch arm 3172. The second contact point 3308 prevents the switch arm3172 from being rotated by the force of the lock spring 3170, thuslocking the switch arm 3172 in position and allowing the cutting forceps3100 to be locked in a closed position.

FIG. 21 illustrates a close-up sideways transparent view of the proximalend of the cutting forceps 3100 shown in FIG. 16, illustrating how thecutting forceps 3100 can be locked in a closed position. Once the lockbutton 3168 has reached the second position, thus locking the switch arm3172 by way of the second contact point 3308, the protrusion 3302 on theend of the switch arm 3172 may now make contact with a lip 3306 on theinside of the switch arm slot 3174. The lip 3306 prevents the switch arm3172 from exiting the switch arm slot 3174, thus locking the arms 3102,3104 of the cutting forceps 3100 in the closed position.

FIG. 22 illustrates a close-up transparent angled view of the switch arm3172 making contact with the lip 3306 in the switch arm slot 3174 of thecutting forceps shown in FIG. 16. The lip 3306 is located such that thefirst end of the switch arm 3172 can only make contact with the lip 3306after the switch arm 3172 has been rotated by the guide 3304 and thedownward force on upper arm 3102. Once the first end is in contact withthe lip 3306, the switch arm 3172 is prevented from rotating out fromunder the lip 3306 by the lock button's 3168 contact with the switch arm3172 at the second contact point 3308.

FIG. 23 illustrates a close-up sideways transparent view of a portion ofthe proximal end of the cutting forceps 3100 shown in FIG. 16,illustrating how the arms 3102, 3104 of the cutting forceps 3100 may beunlocked. By applying pressure 3228 on the distal end of the lock button3168, the lock button can be made to rotate 3230 from the secondposition to the first position, such that the second contact point 3308is removed. Removing the second contact point 3308 allows the switch arm3172 to be driven by the lock spring 3170 back to the neutral position.Once in the neutral position, the switch arm 3172 can exit the switcharm slot 3174.

In some embodiments the switch arm 3172 can also be used to activate, orassist in activating, the RF sealing mechanism. FIG. 24 illustrates asclose-up sideways transparent view of one such embodiment. Asillustrated, the lower arm 3104 may comprise a compression circuit 3176and a compression circuit button 3178. The compression circuit button3178 may be positioned near the bottom of the switch arm slot 3174. Theguide 3304 in the switch arm slot 3174 may change angle near the bottomof the switch arm slot 3174 such that the force required to close thearms 3102, 3104 of the cutting forceps 3100 is not enough for the switcharm 3172 to reach the bottom of the switch arm slot 3174. That is,additional force is required to overcome the additional angle of theguide 3304. Such force can be applied by compressing 3232 the arms 3102,3104 of the cutting forceps 3100 closer together. Once the additionalangle of the guide 3304 is overcome, the switch arm 3172 may makecontact with the compression circuit button 3178 thus activating thecompression circuit 3176. In some embodiments it may not be desirable tolock the switch arm 3172 in a position where the compression circuit3176 is continually activated, instead requiring additional pressure forthe switch arm 3172 to reach the compression circuit button 3178. Inother embodiments it may be desirable to lock the switch arm 3172 suchthat the compression circuit 3176 is active so long as the cuttingforceps 3100 are closed; this may be accomplished, for example, with thelock button 3168.

It should be noted that, while the trigger lockout mechanism and the RFenergy activation mechanism are described as using similar elements, itis understood that not all embodiments require all the elementsdescribed. In some embodiments, only a trigger lockout mechanism isdesired. Such embodiments may comprise the lock button 3168, the lockspring 3170, the switch arm 3172, and the switch arm slot 3174. In otherembodiments, only an RF energy activation mechanism is desired. Suchembodiments may comprise the switch arm 3172, the switch arm slot 3174,the compression circuit 3176, and the compression circuit button 3178.In yet other embodiments, it may be desirable to have both the triggerlockout mechanism and the RF energy mechanism. Such embodiment maycomprise some or all of the parts described.

Various embodiments of the cutting forceps may provide different RFenergy activation schemes. FIG. 25 illustrates the various components ofany of the cutting forceps shown herein that may provide for differentRF energy activation schemes. The illustrated components may or may notall appear in the same embodiment, as described below. FIG. 25illustrates a sideways transparent view of a cutting forceps 4100. Thecutting forceps 4100 is similar to the cutting forceps 100 of FIGS. 1-6.As illustrated in FIG. 25, the cutting forceps 4100 comprises an upperarm 4102 pivotally connected to a lower arm 4104. The upper arm 4102 isconnected to a lower jaw 4110. The lower arm 4104 comprises a lower armbody 4112 and an upper jaw 4116. The lower arm body 4112 comprises anelectrode 4136 for supplying RF energy, wherein the electrode 4136extends from the lower arm body 4112 along the length of the jaws 4110,4116.

In one embodiment of the cutting forceps 4100, the RF energy activationscheme uses an energy button 4142, an energy button circuit (notvisible), a compression circuit 4176, and a compression circuit button4178. The compression circuit 4176 is activated by a switch arm 4172 asdescribed above. In a first RF energy activation scheme, the energybutton 4142 and energy button circuit 4140 activate the electrode 4136to deliver RF energy. Activation of compression circuit button 4178 andcompression circuit 4176 activates an end tone or seal completionsignal, but is not otherwise required to activate the RF energy.

In one embodiment of the cutting forceps 4100, the RF energy activationscheme uses an energy button 4142, an energy button circuit (notvisible), a compression circuit 4176, and a compression circuit button4178. In a second RF energy activation scheme, both the energy buttoncircuit 4140 and the compression circuit 4176 must be activated in orderto activate the RF energy. In such embodiments an end tone or sealcomplete signal may depend on the impedance of tissue held between thejaws 4110, 4116.

In one embodiment of the cutting forceps 4100, the RF energy activationscheme uses an energy button 4142, an energy button circuit (notvisible), a compression circuit 4176, and a compression circuit button4178. In a third RF energy activation scheme, the compression circuitbutton 4178 and the compression circuit 4176 activate the RF energy. Insuch a scheme, the energy activation button 4142 and energy buttoncircuit 4140 need not be provided. In such embodiments an end tone orseal complete signal may depend on the impedance of tissue held betweenthe jaws 4110, 4116.

FIG. 26A illustrates one embodiment of an electrical circuit that mayprovide the necessary power to activate and generate the RF energy. Insome embodiments, the cutting forceps 4100 may be provided with powerfrom an external power source. The external power source is connected tothe cutting forceps 4100 by a cable 4400 that connects to a port 4144located at the proximal end of the lower arm body 4112. Wiring 4402 isprovided within the lower arm body 4112 from the port 4144 to thecompression circuit 4176, the energy button circuit 4140, an electrodeconnector 4152 that is connected to the electrode, and a returnconnector 4158 that comprises the return path for the circuit.

FIG. 26B illustrates one embodiment of the energy button circuit 4140.The energy button circuit 4140 comprises a distal energy button 4404, socalled for the energy button circuit's 4140 location towards the distalend of the device. The distal energy button 4404 is activated by theenergy button 4142, which completes the circuit that provides power tothe electrode 4136.

FIG. 26C illustrates one embodiment of a compression circuit 4176. Insome embodiments, the compression circuit 4176 operates in tandem withthe energy button circuit 4140. For example, in the example illustratedby FIG. 26C, the compression circuit 4176 comprises connections 4406 tothe power source as well as connections 4408 to the energy buttoncircuit. In such embodiments, the circuit is complete only if both thecompression circuit button 4178 and the distal energy button 4404 areactivated. In some embodiments the energy button circuit 4140 is notrequired; in such cases the compression circuit 4176 may only compriseconnections 4406 to the power source. The compression circuit 4176 mayalso comprise one or more resistors 4410.

It is worthy to note that any reference to “one aspect,” “an aspect,”“one embodiment,” or “an embodiment” means that a particular feature,structure, or characteristic described in connection with the aspect isincluded in at least one aspect. Thus, appearances of the phrases “inone aspect,” “in an aspect,” “in one embodiment,” or “in an embodiment”in various places throughout the specification are not necessarily allreferring to the same aspect. Furthermore, the particular features,structures or characteristics may be combined in any suitable manner inone or more aspects.

Although various embodiments have been described herein, manymodifications, variations, substitutions, changes, and equivalents tothose embodiments may be implemented and will occur to those skilled inthe art. Also, where materials are disclosed for certain components,other materials may be used. It is therefore to be understood that theforegoing description and the appended claims are intended to cover allsuch modifications and variations as falling within the scope of thedisclosed embodiments. The following claims are intended to cover allsuch modification and variations.

Although various embodiments have been described herein, manymodifications, variations, substitutions, changes, and equivalents tothose embodiments may be implemented and will occur to those skilled inthe art. Also, where materials are disclosed for certain components,other materials may be used. It is therefore to be understood that theforegoing description and the appended claims are intended to cover allsuch modifications and variations as falling within the scope of thedisclosed embodiments. The following claims are intended to cover allsuch modification and variations.

What is claimed is:
 1. An electrosurgical instrument for operating ontissue, comprising: a first arm, comprising a first handle and a firstjaw; a second arm pivotally connected to the first arm, the second armcomprising a second handle; a second jaw comprising an electrodeoperable to deliver radio frequency (RF) energy to tissue; a knifeconfigured to translate within slots defined in the first and secondjaws; and a push plate operably connected to the knife such that aproximal motion of the push plate extends the knife and a distal motionof the push plate retracts the knife; and a trigger lock mechanismcomprising a switch arm pivotally mounted to the first arm, the switcharm comprising a first end and a second end, wherein the first endextends below the first arm, the trigger lock mechanism configured toprevent the first and second jaw from being opened.
 2. Theelectrosurgical instrument of claim 1, comprising a pull ring integratedinto the push plate for operating the knife.
 3. The electrosurgicalinstrument of claim 1, wherein the first end of the switch arm comprisesa protrusion.
 4. The electrosurgical instrument of claim 1, wherein thetrigger lock mechanism comprises a slot integrated into the lower armand configured to accept the first end of the switch arm, the slotcomprising a guide configured to direct the first end of the switch armin a distal direction, the slot further comprising a lip at the distalside, the lip configured to prevent the first end of the switch arm fromexiting the slot.
 5. The electrosurgical instrument of claim 4, whereinthe guide comprising a ramp upon which the protrusion rides.
 6. Theelectrosurgical instrument of claim 1, comprising a lock spring, whereinthe second end of the switch arm rests against the lock spring andwherein the lock spring is configured to return the switch arm to aneutral position.
 7. The electrosurgical instrument of claim 1, whereinthe first end of the switch arm comprises a lock button pivotallymounted inside the first handle and wherein the switch arm is movablebetween a first position and a second position, wherein the secondposition prevents the switch arm from returning to a neutral position.8. The electrosurgical instrument of claim 7, wherein the switch arm isconfigured to prevent the lock button from transitioning between thefirst position and the second position when the switch arm is in theneutral position.
 9. The electrosurgical instrument of claim 1, thesecond arm further comprising an energy button configured to activatethe RF energy.
 10. An electrosurgical instrument for operating ontissue, comprising: a first arm comprising a first handle and a firstjaw; a second arm pivotally connected to the first arm, the second armcomprising a second handle; a second jaw comprising an electrodeoperable to deliver radio frequency (RF) energy to tissue; a knifeconfigured to translate within slots defined in the first and secondjaws; a push plate operably connected to the knife such that a proximalmotion of the push plate extends the knife and a distal motion of thepush plate retracts the knife; and a trigger lock mechanism configuredto prevent the first and second jaw from being opened; the second armfurther comprising a compression circuit and a compression button foractivating the compression circuit, wherein the compression button islocated at the base of the switch arm slot and is activated by pressureapplied by the switch arm.
 11. The electrosurgical instrument of claim10, comprising a pull ring integrated into the push plate for operatingthe knife.
 12. The electrosurgical instrument of claim 10, wherein thesecond arm comprises an energy button.
 13. The electrosurgicalinstrument of claim 12, wherein the energy button is configured toactivate the RF energy and the compression circuit is configured toenable an end tone.
 14. The electrosurgical instrument of claim 12,wherein the RF energy is activated only when both the energy button andthe compression circuit are activated simultaneously.
 15. Theelectrosurgical instrument of claim 12, wherein the energy button isconfigured to activate the RF energy and the compression circuit isconfigured to activate the RF energy.
 16. The electrosurgical instrumentof claim 10, wherein the compression circuit is configured to enable theRF energy.
 17. An electrosurgical instrument for operating on tissue,comprising: a first arm comprising a first handle and a first jaw; asecond arm pivotally connected to the first arm, the second armcomprising a second handle; a second jaw comprising an electrodeoperable to deliver radio frequency (RF) energy to tissue; a knifeconfigured to translate within slots defined in the first and secondjaws; a push plate operably connected to the knife such that a proximalmotion of the push plate extends the knife and a distal motion of thering retracts the knife; a compression circuit; and a compressioncircuit button configured to activate the compression circuit.
 18. Theelectrosurgical instrument of claim 13 comprising a pull ring integratedinto the push plate for operating the knife.
 19. The electrosurgicalinstrument of claim 17, comprising: a switch arm pivotally mounted tothe first arm, the switch arm comprising a first end and a second end,wherein the first end extends below the first arm; and a switch arm slotintegrated into the lower arm and configured to accept the first end ofthe switch arm; wherein the compression button is located at the base ofthe switch arm slot and is activated by pressure applied by the switcharm.
 20. The electrosurgical instrument of claim 19, wherein the switcharm is configured to required extra pressure on the first arm for theswitch arm to activate the compression button.
 21. The electrosurgicalinstrument of claim 17, comprising an energy button.
 22. Theelectrosurgical instrument of claim 21, wherein the energy button isconfigured to activate the RF energy and the compression circuit isconfigured to enable an end tone.
 23. The electrosurgical instrument ofclaim 17, wherein the RF energy is activated only when both the energybutton and the compression circuit are activated simultaneously.
 24. Theelectrosurgical instrument of claim 17, wherein the energy button isconfigured to activate the RF energy and the compression circuit isconfigured to activate the RF energy.
 25. The electrosurgical instrumentof claim 17, wherein the compression circuit is configured to enable theRF energy.